CN110654510A - Offshore wind power platform group with shared mooring - Google Patents

Abstract

The invention discloses an offshore wind power platform group with shared mooring, wherein the offshore wind power platform group is of a honeycomb type array structure, the honeycomb type array comprises at least one hexagonal unit, the hexagonal unit comprises 3 floating offshore wind power platforms and 3 mooring positions, the floating offshore wind power platforms and the mooring positions are alternately arranged at the angular point positions of the hexagonal unit, and the adjacent floating offshore wind power platforms and the mooring positions are connected through mooring cables. The offshore wind power level platform group sharing the mooring point adopts a mode of sharing the mooring point, so that pile foundations used for mooring are greatly reduced, and the installation cost of the whole offshore wind power plant is reduced.

Description

Offshore wind power platform group with shared mooring

Technical Field

The invention relates to an offshore wind power platform, in particular to an offshore wind power platform sharing a mooring point, and belongs to the field of ocean engineering.

Background

In deep-water offshore wind power, the foundation of the wind power must be abandoned from fixed ocean platforms and adopted to floating ocean platforms due to the water depth. Mooring to secure a floating ocean platform is an alternative. In the mooring mode, the platform can be connected with pile foundations on the seabed through tensioning mooring cables. The general design idea is that each platform is provided with an independent pile foundation for fixing a mooring cable, but the number of platforms of an offshore wind farm is large, which is far higher than that of a traditional offshore oil field platform group, and the pile foundation for mooring is a huge expense during installation. How to fix a large number of offshore wind power platforms by using a relatively small number of mooring points is a problem which needs to be solved in deep water offshore wind power platform group installation.

Disclosure of Invention

The invention aims to solve the technical problem of realizing the mooring of a large batch of deepwater offshore wind power platforms by using a relatively small number of mooring points.

In order to solve the technical problem, the offshore wind power platform group with shared mooring is of a honeycomb type array structure, the honeycomb type array comprises at least one hexagonal unit, the hexagonal unit comprises 3 floating offshore wind power platforms and 3 mooring positions, the floating offshore wind power platforms and the mooring positions are alternately arranged at the angular point positions of the hexagonal unit, and the adjacent floating offshore wind power platforms and the mooring positions are connected through mooring cables.

In the above technical solution, the mooring position is provided with 1 or 2 mooring points.

In the above technical solution, when the mooring station is provided with 2 mooring points, the two mooring points are not on the same horizontal plane, that is, the two mooring points have a height difference.

In the technical scheme, the mooring point comprises a suction pile, a stress column is arranged at the top of the suction pile, a mooring ring is sleeved on the stress column, and a fixing ring is welded at the top of the stress column. The number of mooring rings is 3.

The offshore wind power level platform group sharing the mooring point adopts a mode of sharing the mooring point, so that pile foundations used for mooring are greatly reduced, and the installation cost of the whole offshore wind power plant is reduced.

Drawings

Fig. 1 is a schematic horizontal projection diagram of an offshore wind power platform group with a single mooring point sharing mooring, a circle is a suction pile sharing mooring point, and a pentagon is a wind power and a base platform thereof.

Fig. 2 is a schematic horizontal projection diagram of local conditions of an offshore wind power platform group using double mooring points as a mooring position for shared mooring, wherein a circle is a suction pile shared mooring point, and a pentagon is wind power and a base platform thereof.

Fig. 3 is a structure diagram of an offshore wind power platform group with a single mooring point sharing mooring.

Fig. 4 is a partially enlarged view of fig. 3.

Fig. 5 is a structure diagram of an offshore wind power platform group adopting double mooring points to share mooring.

Fig. 6 is a partially enlarged view of fig. 5.

Fig. 7 is an enlarged view of the docking station employing dual docking points.

Fig. 8 is a view of a suction pile at a mooring point.

Detailed Description

The foundation of the deep-water offshore wind farm is a floating ocean platform, which has high technical similarity with the traditional offshore oil and gas field operation platform, but the ocean platform foundation of the offshore wind farm also has self characteristics according to the special condition of the wind farm. Firstly, the number of ocean platform groups of a wind power plant is huge, the number of the platform groups of an offshore oil and gas field is generally more than ten, the number of the offshore wind power plant is often dozens or even more than one hundred of offshore platforms, and the number of the ocean platforms of the wind power plant is multiple times of that of the offshore platforms of the oil and gas field; secondly, the arrangement of ocean platforms of the wind power plant is regular, the arrangement of the platforms of the offshore oil and gas field is determined according to the position of a well head and is irregular, the wind power utilization rate of the offshore wind power plant is maximized, and the most dense arrangement is achieved under the condition that the requirements of fan spacing and mooring arrangement are met.

The arrangement mode of the offshore wind farm can adopt honeycomb-shaped regular arrangement. The honeycomb shape refers to a honeycomb shape formed by connecting an offshore wind power platform and a mooring position in an offshore wind power platform group through a tensioning mooring cable and projecting the connection on a horizontal plane, and the honeycomb shape is shown in fig. 1. From the single honeycomb, the optimal arrangement is regular hexagon, six sides are equal in length, an included angle is 120 degrees, six sides of the hexagon are sequentially arranged at intervals of a mooring position, a wind power platform, a mooring position and a wind power platform, and finally a plurality of single honeycombs are combined together to form the honeycomb array offshore wind power platform group. According to the requirement of the fan spacing: 7 to 10 blade diameters, it is known that the sides of a rectangle are substantially around 1000 meters. According to the requirements of the mooring cable: the length is 7 times of the water depth, and the distance between the mooring point and the projection of the ocean platform on the horizontal plane is 500-700 meters, so that the mooring position can be just arranged at the center of a circle formed by three wind power platforms to be shared by the three platforms, and the installation cost is saved. The sharing method is a honeycomb array platform group sharing mooring method.

Referring to fig. 1 and 3, an offshore wind power platform group sharing mooring is a honeycomb array structure, the honeycomb array comprises at least one hexagon unit, the hexagon unit comprises 3 floating offshore wind power platforms 1 and 3 mooring positions, the floating offshore wind power platforms 1 and the mooring positions are alternately arranged at the corner positions of the hexagon unit, and the adjacent floating offshore wind power platforms and the mooring positions are connected through tensioning mooring cables 2.

It can also be described as a shared moored offshore wind power platform group, offshore wind power platform group includes at least one triangle-shaped unit, the triangle-shaped unit includes 3 floating offshore wind power platform 1, floating offshore wind power platform 1 sets up the angular point position at triangle-shaped, the focus position of triangle-shaped unit is provided with and is the berth, it sets up 1 or 2 mooring point 3 to be the berth, mooring point 3 is connected with floating offshore wind power platform 1 respectively through tensioning mooring line 2.

Sharing mooring by adopting a honeycomb array offshore wind power platform group requires that each offshore wind power platform is provided with at least 3 groups of mooring cables 2, namely, the included angle between two adjacent groups of mooring cables is 120 degrees, as shown in fig. 1 to 6. Each set of mooring points may match a single or two mooring points 3.

When two mooring points 3 are used, the mooring lines 2 have interaction in a planar projection, as shown in fig. 2, at this time, a connection line of the two mooring points 3 is required to be parallel to one of three sides of a triangle formed by 3 floating offshore wind power platforms 1 sharing the mooring point, and a certain height difference is maintained, see fig. 7, to ensure that there is no interaction in space between the mooring lines.

Neglecting the mooring points at the outermost side of the offshore wind power platform group, the honeycomb-shaped array platform group sharing mooring method can reduce the number of about 2/3 mooring points, and the cost saving effect is obvious.

Referring to fig. 8, the mooring point 3 in the above solution comprises a suction pile 4, the suction pile 4 being attachable to the sea floor for anchoring. The welding of suction pile top has stress column 5, the cover is equipped with 1 to 3 mooring ring 6 on stress column 5, the welding of stress column top has the solid fixed ring 7 with 6 same diameters of mooring ring. The mooring ring 6 can rotate around the stress column 5, and the fixing ring 7 ensures that the mooring ring 6 does not depart from the stress column 5 during operation.

When the mooring operation is carried out at sea, the shared suction pile 4 is well installed in the whole wind power plant in the first step, and when the soil layer around the suction pile 4 is solidified. And secondly, mounting the wind power platform and the wind power equipment. Before installing the suction pile 4, need to construct the place on land and install the back on the mooring ring with the mooring line, transport again to the marine installation to avoid high-priced marine installation expense, when first step suction pile 4 is installed, the other end of mooring line has not been fixed on the platform, and the other end of mooring line is fixed with interim gasbag and floats on the sea when installing this moment, and when waiting for second step installation wind level platform with the other end of mooring line fix on the platform.

Claims (5)

1. The offshore wind power platform group with shared mooring is characterized in that the offshore wind power platform group is of a honeycomb type array structure, the honeycomb type array comprises at least one hexagonal unit, the hexagonal unit comprises 3 floating offshore wind power platforms and 3 mooring positions, the floating offshore wind power platforms and the mooring positions are alternately arranged at the angular point positions of the hexagonal unit, and the adjacent floating offshore wind power platforms and the mooring positions are connected through mooring cables.

2. The offshore wind power platform group with shared mooring of claim 1, wherein the mooring positions are provided with 1 or 2 mooring points.

3. The offshore wind power platform group with shared mooring of claim 2, wherein when 2 mooring points are arranged at the mooring position, the two mooring points are not on the same horizontal plane.

4. The offshore wind power platform group with shared mooring of claim 2 or 3, wherein the mooring point comprises a suction pile, a stress column is arranged at the top of the suction pile, a mooring ring is sleeved on the stress column, and a fixing ring is welded at the top of the stress column.

5. The offshore wind power platform cluster with shared mooring of claim 4, wherein 3 mooring rings are provided.

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